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Analyzing BIG’s Circular Dymak HQ: How Stepped Courtyards Optimize Corporate Spatial Design

2026-07-04Tia Sijabat, Marketing Manager

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What is the Architectural Concept Behind BIG's Circular Footprint?

The architectural concept of the Bjarke Ingels Group (BIG) circular footprint relies on minimizing the building's surface-area-to-volume (S/V) ratio to reduce thermal envelope losses while generating a continuous horizontal workspace loop. This geometry eliminates dead ends, democratizes daylight access across a shallow floor plate, and establishes constant visual connection across the central courtyard.

Why this matters: For architects and corporate real estate specifiers, understanding the mathematical efficiency of a circle is crucial. In high-latitude regions such as Odense, Denmark, maximizing internal thermal performance while keeping building envelopes efficient is a primary driver of sustainable, low-carbon design.

Circular Envelope vs. Traditional Rectilinear Footprint A technical cross-section comparison showing how a circular building envelope with a central courtyard optimizes daylighting, sightlines, and thermal performance compared to a deep-plan rectilinear footprint. CIRCULAR ENVELOPE OPTIMIZED THERMAL & VISUAL PERFORMANCE Direct Solar Inner & Outer Facades 12m Dual-Aspect CENTRAL COURTYARD Thermal Buffer 360° SIGHTLINES Continuous Loop No dead ends, 360° flow Minimised Envelope Lowest surface-to-volume ratio reduces heat loss RECTILINEAR FOOTPRINT TRADITIONAL DEEP-PLAN DARK CORE No Daylight High Corner Heat Loss Deep Plan (30m+) Single Aspect Limited daylight penetration and obstructed views Increased Envelope Higher surface-to-volume ratio increases thermal load
A technical comparison demonstrating how a circular building envelope with a central courtyard minimizes heat loss and maximizes dual-aspect daylighting compared to a deep-plan rectilinear footprint.

By transitioning away from traditional deep-plan rectilinear office layouts, the circular geometry achieves several distinct functional advantages:

  • Unified Circulation: A continuous internal loop eliminates dead-end corridors. This continuous floor plate optimizes cross-departmental collaboration by forcing serendipitous encounters and streamlining horizontal workflows.
  • Democratic Access to Daylight: The narrow, curved floor plate—typically restricted to a depth of 12 to 14 meters—ensures that no workspace is positioned more than 6 to 7 meters away from high-performance external glazing. This spatial organization consistently maintains a Daylight Factor (DF) of over 2.5% across active desk environments.
  • Visual Continuity: The circular geometry allows employees to maintain direct visual contact across the central open-air courtyard. In practical terms, this transverse visibility reduces the physical and psychological isolation often experienced in highly compartmentalized, multi-story office blocks.

How Does the Stepped Courtyard Function as a Microclimatic and Social Hub?

The stepped courtyard at the Dymak Headquarters (HQ) functions as a passive microclimatic engine and central social catalyst by terracing downward toward the south. This orientation maximizes solar radiation capture, acts as a natural wind buffer against harsh North Sea drafts, and provides direct outdoor programmatic extensions for flexible workplace environments.

Why this matters: Outdoor spaces in Northern Europe are often underutilized due to wind chill and low solar altitude. By treating the landscape as an integrated structural element that steps down, BIG creates a sheltered microclimate that extends the seasonal usability of outdoor communal zones by up to six weeks annually.

Solar and Wind Mechanics of the Stepped Courtyard An environmental analysis diagram showing how a stepped courtyard building design maximizes low-angle winter solar penetration on south-facing terraces while deflecting cold northern winds over its tall northern envelope, creating a warm microclimate. Low-Angle Winter Sun Deep solar penetration Southern Exposure Steps down to ground level Temperate Pocket Trapped Warm Air Stepped Terraces • Solar Collectors • Acoustic Baffles Northern Envelope Blocks cold winter winds Cold North Winds Deflected upward SOUTH NORTH
Environmental section analysis demonstrating how the building's southern stepped profile maximizes winter solar exposure while the tall northern mass shields the courtyard from cold prevailing winds.

The thermodynamic and social behavior of this stepped configuration relies on three key design principles:

  • Solar Optimization: By stepping the building's mass down toward the south, the northern portion of the circle remains tall enough to block cold prevailing winds, while the southern terraces allow deep solar penetration into the courtyard floor and adjacent interior zones.
  • Wind Mitigation: The aerodynamic profile of the circular outer envelope diverts incoming wind currents around the building's periphery rather than allowing them to cascade down into the central courtyard. This creates a low-velocity air pocket within the center, drastically improving thermal comfort outdoors.
  • Outdoor Workspace Integration: The stepped terraces act as structural green roofs. Each level is directly accessible via high-performance sliding glass doors, creating a series of elevated, outdoor break rooms and collaborative meeting spaces that blend interior workspaces with the natural landscape.

Circular vs. Traditional Rectilinear Corporate Layouts: A Spatial Comparison

Comparing circular architectural forms to traditional rectilinear office grids reveals substantial differences in spatial efficiency, structural optimization, and environmental response. While linear layouts offer standardized construction modularity, circular designs excel in daylight distribution, passive thermal control, and the elimination of non-functional circulation zones.

Why this matters: Specifiers must balance the premium costs of curved structural elements and specialized glazing against long-term operational savings. Evaluating these typologies through empirical metrics enables data-backed design decisions during early-phase feasibility studies.

Design MetricCircular Layout (e.g., Dymak HQ)Traditional Rectilinear Grid
Circulation EfficiencyHigh; continuous loop with zero dead endsModerate; interrupted by corridors and core shafts
Daylight PenetrationExcellent; maximized by dual-aspect glazing (inner/outer)Variable; deep interior zones often require artificial light
Microclimatic ProtectionSelf-shielding; central courtyard protected from windExposed; linear facades suffer from higher wind loads
Acoustic PerformanceAbsorptive; curved surfaces disperse direct sound wavesReflective; flat, parallel walls amplify reverberation
Biophilic ConnectivityHigh; 360-degree integration with central landscapeLow-to-moderate; exterior views restricted by orientation

From an acoustics perspective, curved interior envelopes perform differently than traditional flat walls. In traditional offices, parallel walls generate standing waves and flutter echoes that elevate ambient noise levels. The curved geometry of a circular layout disperses sound waves obliquely along the perimeter, preventing direct reflection and contributing to a more comfortable acoustic environment when paired with sound-absorptive ceiling materials.


What Material Strategies Define the Dymak HQ’s Structural Framework?

The material strategy of the Dymak HQ relies on a mass timber framework combined with high-performance structural glazing and extensive low-impact landscaping. Utilizing mass timber significantly reduces embodied carbon, while high-performance triple-glazed low-emissivity (low-E) panels provide superior thermal insulation to meet stringent Danish building regulations.

Why this matters: Achieving carbon-neutral certifications like DGNB (Deutsche Gesellschaft für Nachhaltiges Bauen) or LEED (Leadership in Energy and Environmental Design) requires an integrated material-and-energy strategy. The Dymak HQ demonstrates how biophilic material selections can directly align with rigid structural performance criteria.

Cross-Section of High-Performance Curtain Wall and Mass Timber Integration Detailed architectural cross-section showing a triple-glazed low-E curtain wall system structurally connected to a Glulam column and CLT ceiling panel. Triple-Pane Low-E Glass U-value ≤ 0.8 W/m²K Aluminum Mullion Curved structural profile Thermal Break Core Continuous envelope barrier Exposed CLT Ceiling 5-Ply Cross-Laminated Timber Glulam Perimeter Column Structural Post-and-Beam THERMAL BOUNDARY High-performance glazing & thermal breaks limit heat loss. BIOPHILIC INTERIOR Exposed low-VOC solid wood enhances occupant well-being.
Technical cross-section showing the integration of a high-performance triple-glazed curtain wall with an interior mass timber structural system.

The specific material choices that dictate the structural and ecological performance of the building include:

  • Mass Timber Framework: The primary structure utilizes glued laminated timber (Glulam) posts and beams combined with cross-laminated timber (CLT) floor plates. This timber assembly exhibits a high strength-to-weight ratio, with a typical Modulus of Elasticity (MOE) ranging from 11,000 to 12,000 MPa, allowing for long spans with minimal structural depth.
  • High-Performance Facade Glazing: The curtain wall system features triple-glazed units with a Coefficient of Heat Transmission (U-value) of $\le$ 0.8 W/m²K. The glass is treated with low-E coatings that allow high visible light transmission (VLT $\ge$ 70%) while blocking up to 60% of infrared solar heat gain, preventing summertime overheating.
  • Permeable Paving and Green Roofs: The terraced steps are insulated and layered with extensive sedum green roof assemblies and permeable paving stones. These elements act as sustainable urban drainage systems (SUDS), retaining up to 70% of localized precipitation on-site, filtering pollutants, and reducing load on the municipal stormwater infrastructure.
  • Low-VOC Interior Finishes: By leaving the structural timber frame exposed inside the building, the design minimizes the need for drywalls, suspended ceilings, and chemical adhesives. This reduces Volatile Organic Compounds (VOCs) within the workspace, significantly improving indoor air quality and worker health.

FAQ

Why did BIG choose a circular shape for the Dymak HQ?

BIG selected a circular geometry to eliminate hierarchical spatial divisions, create an unbroken loop of collaborative workspaces, and surround a protected outdoor courtyard that serves as the heart of the corporate community. This layout optimizes horizontal paths of travel and increases natural light penetration.

How do stepped courtyards improve building energy efficiency?

Stepped courtyards function as natural light wells, reducing the building's reliance on artificial illumination. Additionally, they shield the central glass facades from harsh perimeter winds, stabilizing indoor temperatures and lowering heating and cooling loads.

Where is the Dymak HQ located, and what does the company do?

The Dymak HQ is located in Odense, Denmark. Dymak is a global supply chain partner specializing in custom packaging, logistics, and display solutions for the horticultural and floral industries, which directly inspired the biophilic design of their headquarters.

What are the primary acoustic benefits of curved architectural forms in offices?

Curved architectural envelopes help disperse interior sound waves rather than reflecting them directly back into the room, which prevents the formation of flutter echoes. When combined with acoustic ceilings, this geometry lowers ambient noise transmission across open-plan workspaces.

How does mass timber construction lower the embodied carbon of a corporate headquarters?

Mass timber utilizes sustainably sourced wood that sequestered carbon dioxide during its growth phase. By substituting traditional reinforced concrete and structural steel with glued laminated timber (Glulam) and cross-laminated timber (CLT), developers can reduce a building's initial embodied carbon footprint by up to 40%.